8,377 research outputs found
Far-Infrared and Submillimeter Observations of High Redshift Galaxies
Observations at far-infrared and submillimeter wavelengths promise to
revolutionize the study of high redshift galaxies and AGN by providing a unique
probe of the conditions within heavily extinguished regions of star formation
and nuclear activity. Observational capabilities in this spectral region will
expand greatly in the next decade as new observatories are developed both in
space and on the ground. These facilities include the Space Infrared Telescope
Facility (SIRTF), the far-infrared and submillimeter telescope (FIRST), and the
millimeter array (MMA). In the longer term, the requirements of high angular
resolution (comparable to that of HST), full wavelength coverage, and high
sensitivity (approaching the fundamental limit imposed by photon counting
statistics) will motivate the development of far-IR and submillimeter space
interferometry using cold telescopes and incoherent detector arrays.Comment: 10 pages, LaTeX, including 5 postscript figures, and requiring
aipproc.sty and epsfig.sty. To appear in the proceedings of the 9th Annual
October Astrophysics Conference in Maryland, ``After the Dark Ages: When
Galaxies were Young", edited by S. S. Holt and E. P. Smit
Collisional excitation of far-infrared line emissions from warm interstellar carbon monoxide (CO)
Motivated by recent observations with Herschel/PACS, and the availability of
new rate coefficients for the collisional excitation of CO (Yang et al. 2010),
the excitation of warm astrophysical CO is revisited with the use of numerical
and analytic methods. For the case of an isothermal medium, results have been
obtained for a wide range of gas temperatures (100 to 5000 K) and H2 densities
(1E+3 to 1E+9 cm-3), and presented in the form of rotational diagrams, in which
the logarithm of the column density per magnetic substate, log (N[J]/g[J]), is
plotted for each state, as a function of its energy, E[J]. For rotational
transitions in the wavelength range accessible to Herschel/PACS, such diagrams
are nearly linear when n(H2) > 1E+8 cm-3. When log10(n[H2]) = 6.8 to 8, they
exhibit significant negative curvature, whereas when log10(n[H2]) < 4.8 the
curvature is uniformly positive throughout the PACS-accessible range. Thus, the
observation of a positively-curved CO rotational diagram does not NECESSARILY
require the presence of multiple temperature components. Indeed, for some
sources observed with Herschel/PACS, the CO rotational diagrams show a modest
positive curvature that can be explained by a single isothermal component.
Typically, the required physical parameters are H2 densities in the 1E+4 to
1E+5 cm-3 range and temperatures, T, close to the maximum at which CO can
survive. Other sources exhibit rotational diagrams with more curvature than can
be accounted for by a single temperature component. For the case of a medium
with a power-law distribution of gas temperatures, with dN/dT proportional to T
to the power -b, results have been obtained for H2 densities 1E+3 to 1E+9 cm-3
and power-law indices, b, in the range 1 to 5; such a medium can account for a
CO rotational diagram that is more positively curved than any resulting from an
isothermal medium.Comment: Accepted for publication in the Astrophysical Journa
Critical Performances
Philosophers of music commonly distinguish performative from critical interpretations. I would like to suggest that the distinction between critical and performative interpretations is well captured by an analogy to legal critics and judges. This parallel draws attention to several features of performative interpretation that are typically overlooked, and deemphasizes epistemic problems with performative interpretations that I believe are typically blown out of proportion and ultimately fail to capture interesting features of performative interpretation. There is an important distinction to be made between critical and performative interpretation, but its source lies in a difference between the authority of critical and performative interpretations
Thermal field theory derivation of the source term induced by a fast parton from the quark energy-momentum tensor
I derive the distribution of energy and momentum transmitted from a fast
parton to a medium of thermalized quarks, or the source term, in perturbative
thermal field theory directly from the quark energy-momentum tensor. The fast
parton is coupled to the medium by adding an interaction term to the
Lagrangian. The thermal expectation value of the energy-momentum tensor source
term is then evaluated using standard Feynman rules at finite temperature. It
is found that local excitations, which are important for exciting an observable
Mach cone structure, fall sharply as a function of the energy of the fast
parton. This may have implications for the trigger dependence of
measurements of azimuthal dihadron particle correlations in heavy-ion
collisions. In particular, a conical emission pattern would be less likely to
be observed for increasing trigger . I show that the results presented in
this paper can be generalized to more realistic modeling of fast parton
propagation, such as through a time dependent interaction term, in future
studies.Comment: Version as accepted by Physical Review D. New version has several
clarifications and added references. 5 pages, 3 figure
Spitzer spectral line mapping of protostellar outflows: II H2 emission in L1157
We present an analysis of Spitzer-IRS spectroscopic maps of the L1157
protostellar outflow in the H2 pure-rotational lines from S(0) to S(7). The aim
of this work is to derive the physical conditions pertaining to the warm
molecular gas and study their variations within the flow. The mid-IR H2
emission follows the morphology of the precessing flow, with peaks correlated
with individual CO clumps and H2 2.12{\mu}m ro-vibrational emission. More
diffuse emission delineating the CO cavities is detected only in the low-laying
transitions, with J(lower) less or equal to 2. The H2 line images have been
used to construct 2D maps of N(H2), H2 ortho-to-para ratio and temperature
spectral index beta, in the assumption of a gas temperature stratification
where the H2 column density varies as T^(beta). Variations of these parameters
are observed along the flow. In particular, the ortho-to-para ratio ranges from
0.6 to 2.8, highlighting the presence of regions subject to recent shocks where
the ortho-to-para ratio has not had time yet to reach the equilibrium value.
Near-IR spectroscopic data on ro-vibrational H2 emission have been combined
with the mid-IR data and used to derive additional shock parameters in the
brightest blue- and red-shifted emission knots. A high abundance of atomic
hydrogen (H/H2 about 0.1-0.3) is implied by the observed H2 column densities,
assuming n(H2) values as derived by independent SiO observations. The presence
of a high fraction of atomic hydrogen, indicates that a partially-dissociative
shock component should be considered for the H2 excitation in these localized
regions. However, planar shock models, either of C- or J-type, are not able to
consistently reproduce all the physical parameters derived from our analysis of
the H2 emission. Globally, H2 emission contributes to about 50% of the total
shock radiated energy in the L1157 outflow.Comment: 31 pages, 9 figure, Accepted for publication on Ap
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